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arxiv: 2208.14050 · v1 · pith:THUL74FF · submitted 2022-08-30 · physics.atom-ph · quant-ph

Low-energy electron-induced ion-pair dissociation to "Trilobite-resembling" long-range heavy Rydberg system

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classification physics.atom-ph quant-ph
keywords dissociationenergyion-pairanionicatomicelectron-inducedfragmentsheavy
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We have studied electron-induced ion-pair dissociation dynamics of CO using the state-of-art velocity map imaging technique in combination with a time-of-flight-based two-field mass spectrometer. Extracting the characteristics for O$^-$/CO nascent atomic anionic fragments from the low energy (25 - 45 eV) electron-molecule scattering, first-time, we have directly detected the existence of S-wave resonated Trilobite resembling a novel molecular binding energy mechanism, as predicted by Greene \textit{et al.} \cite{greene2000creation}. The energy balance demands ion-pair dissociation (IPD) lie within a long-range (<1000 Bohr radius) heavy Rydberg system. Modified Van Brunt expression capturing the deflection of dipole-Born approximation is used to model the angular distributions (AD) for the anionic atomic fragments. The AD fits reveal that the final states are dominantly associated with $\Sigma$ symmetries and a minor contribution from $\Pi$ symmetric states that maps the three-dimensional unnatural oscillation of Born-Oppenheimer's potential.

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Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Electron-Impact Quasi-Resonant Ion-Pair Dissociation of OCS: A Velocity Slice Imaging Study with Partial Wave Analysis

    physics.atm-clus 2026-04 unverdicted novelty 6.0

    Electron impact on OCS produces two ion-pair dissociation pathways through hybrid Rydberg-ion-pair superexcited states, with fragment angular distributions showing beta greater than 1 and energy-dependent partial wave shifts.